Tandem mass spectrometric characterization of bile acids and steroid conjugates based on low-energy collision-induced dissociation

We examined the characteristics of several bile acids and some steroid conjugates under low-energy-collision-induced dissociation conditions using a triple quadrupole tandem mass spectrometer. According to conjugation types, we observed characteristic product ions and/or neutral losses in the product ion spectra. Amino acid conjugates afforded specific product ions. For example, glycine-conjugated metabolites routinely produced a product ion at m/z 74, and taurine-conjugated metabolites produced product ions at m/z 124, 107, and 80. When a strong peak appeared at m/z 97, the molecule contained a sulfate group. In contrast to amino acid conjugates, carbohydrate conjugates required a combination of product ions and neutral losses for identification. We could discriminate a glucoside from an acyl galactoside according to the presence or absence of a product ion at m/z 161 and a neutral loss of 180 Da. Discrimination among esters, aliphatic ethers, and phenolic ether types of glucuronides was based upon differences in the intensities of a product ion at m/z 175 and a neutral loss of 176 Da. Furthermore, N-acetylglucosamine conjugates showed a characteristic product ion at m/z 202 and a neutral loss of 203 Da, and the appearance of a product ion at m/z 202 revealed the existence of N-acetylglucosamine conjugated to an aliphatic hydroxyl group without a double bond in the immediate vicinity.Together, the data presented here will help to enable the identification of unknown conjugated cholesterol metabolites by using low-energy collision-induced dissociation.     

Determination of N-acetylneuraminic acid by gas chromatography-mass spectrometry with a stable isotope as internal standard

N-Acetylneuraminic acid was determined by gas chromatography-mass spectrometry using selected ion-monitoring technique with N-[²H₃]acetylneuraminic acid as an internal standard. M-COOTMS fragments at $\text{m}\text{z}$ 624 of trimethylsilyl derivatives of N-acetylneuraminic acid and at $\text{m}\text{z}$ 627 of that of the internal standard were used as monitoring ions. The standard curve obtained was linear in the range of over 10³, and the lower limit for quantitation was estimated to be a few hundred picograms. This method was used to measure total N-acetylneuraminic acid in the plasma of healthy humans and patients with lung cancer. The total N-acetylneuraminic acid level in the plasma was two to three times higher in the patients than in controls. A few hundred nanoliters of plasma was sufficient for the analysis. The mass fragmentogram of plasma gave a good signal/noise ratio, and measurements were very specific, accurate, and reproducible.     

Electrospray mass spectrometry of cis-[Ru(NO)Cl(bpy)2] (bpy=2,2-bipyridine): fragmentation from desolvated {[Ru(NO)Cl(bpy)2], Cl} ion pairs by electron transfer and internal Lewis base pathways

The electrospray mass spectrum (ESI-MS) of cis-[Ru(NO)Cl(bpy)₂]Cl₂ (bpy=2,2^′-bipyridine), obtained from 50% CH₃OH/50% H₂O as the mobile solvent, exhibited ruthenium-containing ions derived from a {[Ru^II(NO⁺)Cl(bpy)₂]²⁺, Cl⁻}⁺ ion pair (m/z=514) and [Ru^II(NO⁺)Cl(bpy)₂]²⁺ (m/z=239.5). [Ru^IIICl(bpy)₂]²⁺, from the loss of NO from the 239.5 ion, is detected at m/z=224.5. Only the m/z 514 ion pair is detected when 100% CH₃OH mobile solvent is used, but the presence of even small amounts of water prompted the additional detection of the m/z 239.5 and m/z 224.5 ions under tandem MS-MS conditions. Ruthenium-chloro-containing ions appear as a characteristic collection of eight main, and four lesser, intense ions created from combinations ¹⁰⁴Ru, ¹⁰²Ru, ¹⁰¹Ru, ⁹⁹Ru, ⁹⁸Ru, ⁹⁶Ru, ³⁵Cl and ³⁷Cl isotopes with minor contributions from ¹³C, etc. For convenience of discussion, only the most abundant m/z species are mentioned herein as representative of all the isotopically distributed ions.Four fragmentation channels are detectable from the m/z=514 chloride ion pair: (1) the loss of HCl (main channel; ca. 50% of fragmentation events), (2) the loss of NO (ca. 12% ), (3) the loss of bpy (minor pathway), and (4) the loss of Cl atom (ca. 38% ).Loss of NO from ion m/z 514 yields ion m/z 484, which is the precursor of ions m/z 448 (by loss of HCl), m/z 328 (by loss of bpy) and m/z 292 (by loss of HCl and bpy). Loss of HCl from ion m/z 514 generates ion m/z 478, [Ru^II(NO⁺)Cl(bpyH)(bpy-H)]⁺, deprotonated at the ortho C-H of one bpy ligand. In MS-MS experiments, the m/z 478 ion was established to undergo loss of NO, producing ion m/z 448, rejoining further fragmentation process for ion m/z 448 at this point. Loss of neutral bipyridine from m/z 514 in low yield produces ion m/z 358, which undergoes further loss of NO to form [RuCl₂(bpy)]⁺ ion (m/z=328). MS-MS “neutral loss of 30” spectra confirmed the NO loss events as part of the fragmentation sequence for all four pathways.A fourth species of m/z=479 from the “514” ion is obtained by an internal electron transfer from Cl⁻ of the ion pair, and loss of the resultant neutral Cl atom. The product [Ru^II(NO^·)Cl(bpy)₂]⁺ “479” fragment undergoes facile loss of NO to generate [Ru^IICl(bpy)₂]⁺ (m/z=449). Ion m/z 449 gives rise to ions m/z 413 (loss of HCl) and m/z 257(loss of HCl and bpy). MS-MS experiments confirm the neutral loss of Cl from the m/z 514 ion, and the formation of the m/z 449 ion via m/z 479 and m/z 514 parents. This pathway was not observed in a prior study for the related complex, [Ru(NO)Cl(dpaH)(dpa⁻)]⁺ (dpaH=2,2^′-dipyridylamine), which does not have an external Cl⁻ in an ion pair.     

Biodegradation of microcystin-LR and-RR by a novel microcystin-degrading bacterium isolated from Lake Taihu

Microcystin-LR (MC-LR) and microcystin-RR (MC-RR) are the two most common microcystins (MCs) present in fresh water posing a direct threat to public health because of their hepatotoxicity. A novel MC-degrading bacterium designated MC-LTH1 capable of degrading MC-LR and -RR was isolated, and the degradation rates and mechanisms of MC-LR and -RR for this bacterium were investigated. The bacterium was identified as Bordetella sp. and shown to possess a homologous mlrA gene responsible for degrading MCs. To the best of our knowledge, this is the first report of mlrA gene detection in Bordetella species. MC-LR and -RR were completely degraded separately at rates of 0.31 mg/(L h) and 0.17 mg/(L h). However, the degradation rates of MC-LR and -RR decreased surprisingly to 0.27 mg/(L h) and 0.12 mg/(L h), respectively, when both of them were simultaneously present. Degradation products were identified by high performance liquid chromatography coupled with time-of-flight mass spectrometry. Adda (m/z 332.2215, C₂₀H₂₉NO₃) commonly known as a final product of MC degradation by isolated bacteria was detected as an intermediate in this study. Linearized MC-LR (m/z 1013.5638, C₄₉H₇₆N₁₀O₁₃), linearized MC-RR (m/z 1056.4970, C₄₉H₇₇N₁₃O₁₃), and tetrapeptide (m/z 615.3394, C₃₂H₄₆N₄O₈) were also detected as intermediates. These results indicate that the bacterial strain MC-LTH1 is quite efficient for the detoxification of MC-LR and MC-RR, and possesses significant bioremediation potential.     

Mechanism of Reactive Orange 16 degradation with the white rot fungus Irpex lacteus

The study focuses on the Reactive Orange 16 (RO16) degradation products obtained by fungal treatment of the dye. Eighty percent of dye decolorization was achieved within 24 h by Irpex lacteus cultures immobilized on polyurethane foam (PUF). Dye degradation products were investigated using LC–MS analysis. Three compounds were identified as the dye intermediates: 6-acetamido-3,4-dioxo-3,4-dihydronaphthalene-2-sulfonate (m/z 294), (E)-2-(4-acetamidophenyl)-1-carboxyethenesulfonate (m/z 284), and 4-(2-hydroxyethylsulfonyl)phenolate (m/z 201). Despite significant laccase activities detected in the fungal cultures, no backward polymerization of the reaction products resulting in recurrent colorization was observed after fungal treatment of the dye solution.     

Enzymatic grafting of functional molecules to the lignin model dibenzodioxocin and lignocellulose material

Laccase-mediated grafting of functional molecules presents an eco-friendly approach to functionalize lignocellulose materials. In this study functional molecules in the form of reactive phenolic amines, hydrophobicity enhancing fluorophenols and selected wood preservatives, were for the first time successfully coupled onto the lignin model compound dibenzodioxocin (Db) as demonstrated by HPLC-MS analysis. A 1:1-coupling was demonstrated for various combinations including Db and tyramine (m/z 620.5), Db and 3-O-methyldopamine (m/z 650.5), Db and 4-hydroxy-3-methoxybenzylamine (m/z 636.5), Db and 4-fluoro-2-methylphenol (m/z 609.5), and Db and 2-phenylphenol (m/z 653.5). Fungal laccases from Trametes hirsuta and T. villosa were more efficient in mediating the coupling of tyramine to dibenzodioxocin and beech (Fagus sylvatica) wood than a Bacillus sp. laccase with lower redox potential. This work presents for the first time a model for functionalizing of lignocellulose using the lignin model dibenzodioxocin.     

Simultaneous quantification of rosiglitazone and its two major metabolites,N-desmethyl and p-hydroxy rosiglitazone in human plasma by liquid chromatography/tandem mass spectrometry: Application to a pharmacokinetic study

We present a simple, rapid, and sensitive liquid chromatography (LC)–tandem mass spectrometry (MS/MS) method for the simultaneous quantification of rosiglitazone and its two major metabolites via CYP2C8/9, N-desmethyl and p-hydroxy rosiglitazone, in human plasma. The procedure was developed and validated using rosiglitazone-d₃ as the internal standard. Plasma samples (0.1 ml) were prepared using a simple deproteinization procedure with 0.2 ml of acetonitrile containing 40 ng/ml of rosiglitazone-d₃. Chromatographic separation was carried out on a Luna C₁₈ column (100 mm × 2.0 mm, 3-μm particle size) using an isocratic mobile phase consisting of a 60:40 (v/v) mixture of acetonitrile and 0.1% formic acid_(aq). Each sample was run at 0.2 ml/min for a total run time of 2.5 min per sample. Detection and quantification were performed using a mass spectrometer in selected reaction-monitoring mode with positive electrospray ionization at m/z 358.1 → 135.1 for rosiglitazone, m/z 344.2 → 121.1 for N-desmethyl rosiglitazone, m/z 374.1 → 151.1 for p-hydroxy rosiglitazone, and m/z 361.1 → 138.1 for rosiglitazone-d₃. The linear ranges of concentration for rosiglitazone, N-desmethyl rosiglitazone, and p-hydroxy rosiglitazone were 1–500, 1–150, and 1–25 ng/ml, respectively, with a lower limit of quantification of 1 ng/ml for all analytes. The coefficient of variation for assay precision was less than 14.4%, and the accuracy was 93.3–112.3%. No relevant cross-talk and matrix effect were observed. This method was successfully applied to a pharmacokinetic study after oral administration of a 4-mg rosiglitazone tablet to healthy male Korean volunteers.     

A sensitive and specific assay for glutathione with potential application to glutathione disulphide,using high-performance liquid chromatography–tandem mass spectrometry

We have utilised the combination of sensitivity and specificity afforded by coupling high-performance liquid chromatography (HPLC) to a tandem mass spectrometer (MS–MS) to produce an assay which is suitable for assaying glutathione (GSH) concentrations in liver tissue. The sensitivity suggests it may also be suitable for extrahepatic tissues. The method has been validated for GSH using mouse liver samples and also allows the assay of GSSG. The stability of GSH under conditions relevant to the assay has been determined. A 20-μl amount of a diluted methanol extract of tissue is injected with detection limits of 0.2 pmol for GSH and 2 pmol for GSSG. The HPLC uses an Altima C₁₈ (150×4.6 mm, 5 μm) column at 35°C. Chromatography utilises a linear gradient from 0 to 10% methanol in 0.1% formic acid over 5 min, with a final isocratic stage holding at 10% methanol for 5 min. Total flow rate is 0.8 ml/min. The transition from the M+H ion (308.1 m/z for GSH, and 613.3 m/z for GSSG) to the 162.0 m/z (GSH) and 355.3 m/z (GSSG) fragments are monitored.     

Simultaneous determination of puerarin,daidzein, baicalin,wogonoside and liquiritin of GegenQinlian decoction in rat plasma by ultra-performance liquid chromatography–mass spectrometry

A specific ultra-performance liquid chromatography–mass spectrometry (UPLC–MS) method was developed for the simultaneous determination of puerarin, daidzein, baicalin, wogonoside and liquiritin in rat plasma. Chromatographic separation was performed on a C₁₈ column packed with 1.7 μm particles by a linear gradient elution. The analytes and carbamazepine (internal standard, I.S.) were monitored in a selected-ion reaction (SIR) mode with a positive electrospray ionization (ESI) interface by the following ions: m/z 417.2 for puerarin, m/z 255.2 for daidzein, m/z 271.0 for baicalin, m/z 461.0 for wogonoside, m/z 441.0 for liquiritin and m/z 237.2 for carbamazepine (I.S.), respectively. The calibration curves of these analytes were linear over the concentration ranges from 0.00254–1.02 μg mL^?1 to 0.0102–10.2 μg mL^?1. Within-batch and between-batch precisions (RSD%) were all within 15% and accuracy (RE%) ranged from ?10% to 10%. The extraction recoveries were on average 79.8% for puerarin, 90.8% for daidzein, 74.4% for baicalin, 70.2% for wogonoside and 84.7% for liquiritin. The validated method was successfully applied to investigate the pharmacokinetics of five bioactive compounds of GegenQinlian decoction (GQD) in rats.     

Determination of 11-nor-Δ9-tetrahydrocannabinol-9-carboxylic acid in urine using high-performance liquid chromatography and electrospray ionization mass spectrometry

High-performance liquid chromatography with electrospray ionization mass spectrometry was used to determine 11-nor-Δ⁹-tetrahydrocannabinol-9-carboxylic acid (THC-COOH) in urine. After basic hydrolysis of conjugates, the compound was extracted using SPEC-PLUS-3ML-C₁₈ solid-phase extraction columns. A deuterium labelled internal standard (d₃-THC-COOH) was added prior to hydrolysis. Separation was performed on a reversed-phase Zorbax Eclipse XDB-C₈ analytical column (150×3.0 mm I.D.) using a gradient program from 60 to 80% acetonitrile (4 mM formic acid) at a flow-rate of 0.5 ml/min. The compounds were detected by single ion monitoring of m/z 345 and m/z 348 for the protonated molecules [THC-COOH+H]⁺ and [d₃-THC-COOH+H]⁺, respectively. The precision and accuracy were tested on spiked urine samples in the range 2.5–125 ng/ml. The mean recovery was 95% (n=58), coefficients of variations were 2.2–4.3% and the limit of detection 2 ng/ml. Diagnostic qualifying ions of THC-COOH (m/z 327 and m/z 299) and d₃-THC-COOH (m/z 330) were generated using up-front collision-induced dissociation. The relative ion intensities in clinical samples (n=21) were within ±20% deviation compared with standards. Using this tolerance and the presence of the ions m/z 327 and m/z 299 at the correct retention times as the acceptance criteria for identification of THC-COOH positive samples, the limit of detection was 15 ng/ml. The LC–MS method complies with the current recommendations on drugs of abuse testing, in which mass spectrometric detection is emphasized.     

Crystal structures of DNA:DNA and DNA:RNA duplexes containing 5-(N-aminohexyl)carbamoyl-modified uracils reveal the basis for properties as antigene and antisense molecules

Oligonucleotides containing 5-(N-aminohexyl)carbamoyl-modified uracils have promising features for applications as antigene and antisense therapies. Relative to unmodified DNA, oligonucleotides containing 5-(N-aminohexyl)carbamoyl-2′-deoxyuridine (^NU) or 5-(N-aminohexyl)carbamoyl-2′-O-methyluridine (^NU_m), respectively exhibit increased binding affinity for DNA and RNA, and enhanced nuclease resistance. To understand the structural implications of ^NU and ^NU_m substitutions, we have determined the X-ray crystal structures of DNA:DNA duplexes containing either ^NU or ^NU_m and of DNA:RNA hybrid duplexes containing ^NU_m. The aminohexyl chains are fixed in the major groove through hydrogen bonds between the carbamoyl amino groups and the uracil O4 atoms. The terminal ammonium cations on these chains could interact with the phosphate oxygen anions of the residues in the target strands. These interactions partly account for the increased target binding affinity and nuclease resistance. In contrast to ^NU, ^NU_m decreases DNA binding affinity. This could be explained by the drastic changes in sugar puckering and in the minor groove widths and hydration structures seen in the ^NU_m containing DNA:DNA duplex structure. The conformation of ^NU_m, however, is compatible with the preferred conformation in DNA:RNA hybrid duplexes. Furthermore, the ability of ^NU_m to render the duplexes with altered minor grooves may increase nuclease resistance and elicit RNase H activity.     

GC–MS analysis of S-nitrosothiols after conversion to S-nitroso-N-acetyl cysteine ethyl ester and in-injector nitrosation of ethyl acetate

S-Nitrosothiols from low-molecular-mass and high-molecular-mass thiols, including glutathione, albumin and hemoglobin, are endogenous potent vasodilators and inhibitors of platelet aggregation. By utilizing the S-transnitrosation reaction and by using the lipophilic (pK_L 0.78) and strong nucleophilic synthetic thiol N-acetyl cysteine ethyl ester (NACET) we have developed a GC–MS method for the analysis of S-nitrosothiols and their ¹⁵N- or ²H–¹⁵N-labelled analogs as S-nitroso-N-acetyl cysteine ethyl ester (SNACET) and S¹⁵NACET or d₃-S¹⁵NACET derivatives, respectively, after their extraction with ethyl acetate. Injection of ethyl acetate solutions of S-nitrosothiols produced two main reaction products, compound X and compound Y, within the injector in dependence on its temperature. Quantification was performed by selected-ion monitoring of m/z 46 (i.e., [NO₂]^?) for SNACET and m/z 47 (i.e., [¹⁵NO₂]^?) for S¹⁵NACET/d₃-S¹⁵NACET for compound X, and m/z 157 for SNACET and m/z 160 for d₃-S¹⁵NACET for compound Y. In this article we describe the development, validation and in vitro and in vivo applications of the method to aqueous buffered solutions, human and rabbit plasma. Given the ester functionality of SNACET/S¹⁵NACET/d₃-S¹⁵NACET, stability studies were performed using metal chelators and esterase inhibitors. The method was found to be suitable for the quantitative determination of various S-nitrosothiols including SNACET externally added to human plasma (0–10 μM). Nitrite contamination in ethyl acetate was found to interfere. Our results suggest that the concentration of endogenous S-nitrosothiols in human plasma does not exceed about 200 nM in total. Oral administration of S¹⁵NACET to rabbits (40–63 μmol/kg body weight) resulted in formation of ALB-S¹⁵NO, [¹⁵N]nitrite and [¹⁵N]nitrate in plasma.     

N-(m-[125I]iodophenyl)maleimide: an agent for high yield radiolabeling of antibodies

In an effort to radiolabel antibodies, N-(m-[¹²⁵I]iodophenyl)maleimide (m-[¹²⁵I]IPM) was prepared by the demetallation of an N-[m-tri-(n-butyl)stannylphenyl]maleimide intermediate. The unlabeled intermediate was synthesized in ⩾ 75% yield using a palladium catalyzed reaction of hexabutylditin with m-bromoaniline, followed by reaction with maleic anhydride and ring annulation. All products were confirmed by NMR and elemental analysis. Labeling with ¹²⁵I was carried out in a biphasic mixture containing chloramine-T (radiochemical yield ⩾ 70%). Rabbit IgG modified with the heterobifunctional crosslinking agent N-succinimidyl-3-(2-pyridyldithio)propionate (SPDP) and bovine serum albumin were conjugated with m-[¹²⁵I]IPM (yield: 40 and 80%, respectively). In addition, m-[¹²⁵I]IPM was conjugated to rabbit IgG subunits (HL) in 70% yield. The in vitro stability of the radiolabeled proteins in serum showed < 1% deiodination over 24 h.     

Eco-friendly biodegradation of a reactive textile dye Golden Yellow HER by Brevibacillus laterosporus MTCC 2298

Brevibacillus laterosporus MTCC 2298 showed 87% decolorization of Golden Yellow HER within 48 h under static condition at the concentration 50 mg l^?1; however no significant change in the decolorization performance was observed under shaking condition. Decolorization performance was maximum (74%) at the pH 7.0 and 30 °C. TLC and HPLC analysis confirmed the biodegradation of Golden Yellow HER. Biodegradation pathway was proposed using GC–MS and FTIR spectral analysis. Mainly elected metabolites are the 2,5-Dichloro-4 (3-hydrazino-2-hydroxy cyclopentylamino-) dibenzene-sulfonic acid (peak 1, m/z = 526), 4-(3-hydrazino-2-hydroxy cyclopentylamino)-benzene-sulfonic acid (peak 2, m/z = 455), 4-(3-amino-2-hydroxy-cyclopentylamino)-benzene-sulfonic acid and 5-amino-cyclohex-3-ene-sulfonic acid (peak 3, m/z = 183). Phytotoxicity results suggested that degradation products of Golden Yellow HER are non-toxic to the common crops such as Sorghum vulgare and Phaseolus mungo. Also, degradation products are non-toxic to B. laterosporus as well as ecologically important bacteria like Pseudomonas aeruginosa and Azotobacter vinelandii.     

99mTc-tricarbonyl labeled agents for cell labeling: Development,biodistribution in normal mice and preliminary in vitro evaluation

We have developed four ^99mTc(CO)₃-labeled lipophilic tracers as potential radiolabeling agents for cells based on a hexadecyl tail. ^99mTc(CO)₃-hexadecylamino-N,N′-diacetic acid (negatively charged), ^99mTc(CO)₃-hexadecylamino-N-α-picolyl-N′-acetic acid (uncharged), ^99mTc(CO)₃-N,N′-dipicolylhexadecylamine (positively charged), ^99mTc(CO)₃-N-hexadecylaminoethyl-N′-aminoethylamine (positively charged) were prepared in a radiolabeling yield: >90%. Preliminary cell uptake studies were performed in mixed blood cells with or without plasma and were compared with ^99mTc-d,l-HMPAO and [¹⁸F]FDG. In plasma-free blood cells, maximum uptake (78%) was obtained for ^99mTc(CO)₃-N-hexadecylaminoethyl-N′-aminoethylamine after 60 min incubation (compared to 55% and 23% for ^99mTc-d,l-HMPAO and [¹⁸F]FDG, respectively) while in plasma-rich medium, ^99mTc(CO)₃-N,N′-dipicolylhexadecylamine was best bound (54%, similar to the binding of ^99mTc-d,l-HMPAO). Biodistribution in normal mice showed mainly hepatobiliary clearance of the agents and initial high lung uptake. The radiolabeled compounds showed good blood clearance with maximally 7.9% injected dose per gram at 60 min post injection. While the least lipophilic agent (^99mTc(CO)₃-N,N′-dipicolylhexadecylamine, log P = 1.3) showed the best cell uptake, there appears to be no direct correlation between lipophilicity and tracer uptake in mixed blood cells. In view of its comparable cell uptake to well known cell labeling agent ^99mTc-d,l-HMPAO, ^99mTc(CO)₃-N,N′-dipicolylhexadecylamine merits further evaluation as a potential cell labeling agent.     

Unique pentafluorobenzylation and collision-induced dissociation for specific and accurate GC–MS/MS quantification of the catecholamine metabolite 3,4-dihydroxyphenylglycol (DHPG) in human urine

In the human body, the catecholamine norepinephrine is mainly metabolized to 3,4-dihydroxyphenylglycol (DHPG) which therefore serves as an important biomarker for norepinephrine's metabolism. Most data on DHPG concentrations in human plasma and urine has been generated by using HPLC-ECD or GC–MS technologies. Here, we describe a stable-isotope dilution GC–MS/MS method for the quantitative determination of DHPG in human urine using trideutero-DHPG (d₃-DHPG) as internal standard and a two-step derivatization process with pentafluorobenzyl bromide (PFB-Br) and N,O-bis(trimethylsilyl)trifluoroacetamide (BSTFA). Two pentafluorobenzyl (PFB) trimethylsilyl (TMS) derivatives were obtained and identified, i.e., two isomeric DHPG-PFB-(TMS)₃ derivatives and the later eluting DHPG-tetrafluorobenzyl-(TMS)₂ derivative, i.e., DHPG-TFB-(TMS)₂. To our knowledge the DHPG-TFB-(TMS)₂ derivative and the underlying reaction have not been reported previously. In this reaction both vicinal aromatic hydroxyl groups of DHPG react with PFB-Br to form a heterocyclic seven-membered [1,4]dioxepin compound. The DHPG-TFB-(TMS)₂ derivative was used for quantitative GC–MS/MS analysis in the electron-capturing negative-ion chemical ionization mode by selected-reaction monitoring of m/z 351 from m/z 401 for DHPG and of m/z 352 from m/z 404 for d₃-DHPG. Validation experiments on human urine samples spiked with DHPG in a narrow (0–33 nM) and a wide range (0–901 nM) revealed high recovery (86–104%) and low imprecision (RSD; 0.01–2.8%). LOD and relative LLOQ (rLLOQ) values of the method for DHPG were determined to be 76 amol and 9.4%, respectively. In urine of 28 patients suffering from chronic inflammatory rheumatic diseases, DHPG was measured at a mean concentration of 238 nM (38.3 μg/g creatinine). The DHPG concentration in the respective control group of 40 healthy subjects was measured to be 328 nM (39.2 μg/g creatinine). Given the unique derivatization reaction and collision-induced dissociation, and the straightforwardness the present method is highly specific, accurate, precise, and should be useful in clinical settings.     

Synthesis, characterization and X-ray crystal structure of [Re(L4)(CO)3]Br · 2CH3OH (L4 = N,N-bis[(2-diphenylphosphino)ethyl]methoxyethylamine): A model compound for novel cationic Tc(I)-tricarbonyl radiotracers useful for heart imaging

This report describes synthesis and evaluation of cationic complexes, [^99mTc(CO)₃(L)]⁺ (L = N-methoxyethyl-N,N-bis[2-(bis(3-ethoxypropyl)phosphino)ethyl]amine (L1), N-[(15-crown-5)-2-yl]-N,N-bis[2-(bis(3-ethoxypropyl)phosphino)ethyl]amine (L2) and N-[(18-crown-6)-2-yl]-N,N-bis[2-(bis(3-ethoxypropyl)phosphino)ethyl]amine (L3)) as potential radiotracers for heart imaging. Preliminary results from biodistribution studies in female adult BALB-c mice indicated that the cationic ^99mTc(I)-tricarbonyl complex, [^99mTc(CO)₃(L2)]⁺, has a significant localization in the heart at 60 min post-injection. To understand the coordination chemistry of these bisphosphine ligands with the ^99mTc(I)-tricarbonyl core, we prepared [Re(CO)₃(L4)]Br (L4: N,N-bis[(2-diphenylphosphino)ethyl]methoxyethylamine) as a model compound. [Re(CO)₃(L4)]Br has been characterized by elemental analysis, IR, ESI-MS, NMR (¹H, ¹³C, ¹H-¹H COSY, and ¹H-¹³C HMQC) methods, and X-ray crystallography. In solid state, [Re(CO)₃(L4)]⁺ has a distorted octahedron coordination geometry with PNP occupying one facial plane. The chelator backbone adopts a “chair” conformation with phosphine-P atoms at equatorial positions and the amine-N at the apical site. In solution, [Re(CO)₃(L4)]⁺ is able to maintain its cationic nature with no dissociation of carbonyl ligands or any of the three PNP donors.     

In vivo passages of heterologous Beauveria bassiana isolates improve conidial surface properties and pathogenicity to Nilaparvata lugens (Homoptera: Delphacidae)

In entomopathogenic hyphomycetes, desired candidates against the brown planthopper, Nilaparvata lugens (a sap-sucking rice pest in Asia), are lacking. In this study, 21 Beauveria bassiana isolates from heterologous host insects showed low pathogenicity to third-instar nymphs sprayed at the high concentration of ∼1000 conidia/mm², causing only 2-23% mortalities. Of those, three isolates killed significantly more nymphs (up to 45-62%) after two in vivo passages but no more after further passage. Conidial hydrophobicity rates (H_r), zeta potentials (P_z), and subtilisin-like protease (Pr1) activities (A_p) of these isolates showed the same trends in the three host passages (N: 0-3). In multivariate correlation, the variables N, H_r and P_z were found contributing 89% to the mortality variation (r² = 0.89). Significant positive correlations were also found between H_r and N (r² = 0.64), P_z and N (r² = 0.52), A_p and N (r² = 0.51), H_r and A_p (r² = 0.45), and P_z and A_p (r² = 0.57), respectively. However, irregular changes of H_r and P_z occurred in four other isolates, whose pathogenicity to N. lugens was not enhanced by repeated host passages, resulting in no correlation between the variables. Our data indicate that the conidial surface properties H_r and P_z associated with cuticle adhesion reflect the heterologous host-induced adaptation and help to select fungal candidates against N. lugens from repeated in vivo passages.     

Amdxidation and demethylation of N,N-dimethylaniline by rabbit liver and lung microsomes effects of age and metals

Lung N-oxidase enzyme activity was about three times higher than liver N-oxidase at the pH optimum, about pH 8.9, whereas the activities were nearly the same at more physiological ranges of pH. The lung N-oxidase was also stimulated about 2-fold by 100 mM Mg²⁺ and by 0.1 mM Hg²⁺, whereas liver N-oxidase activity was inhibited by these concentrations of ions. The difference in response of liver and lung enzymes to Mg²⁺ and Hg²⁺ was not altered by preparing the microsomes in the presence of 50 mM ethylenediamine tetraacetic acid (EDTA) in 0.1 M Tris (hydroxymethyl) amino methane (Tris) buffer or 50 mM EDTA in 0.1 M KPO₄ buffer, both at pH 7.6, indicating that the differences are probably not due to the presence of endogenous metals. The difference between the liver and lung N-oxidase systems may be due to the tissue environment rather than to the enzyme itself since mercury stimulation of lung N-oxidation began to disappear upon partial purification of the N-oxidase enzymes. In contrast to the effects of Hg²⁺ and Mg²⁺, 1 mM Ni²⁺ enhanced liver N-oxidase activity about 30% and 5 mM Ni²⁺ stimulated lung enzyme activity about 30% whereas concentrations above 10 mM were inhibitory to both N-oxidases. Both liver and lung demethylase activities were inhibited by these concentrations of Mg²⁺, Hg²⁺ and Ni²⁺.Various suifhydryl reagents were also tested for their effects on these enzymes. The mercurials, para-chloromercurybenzoate (pCMB) and phenylmercuryacetate (PMA) at concentrations of 0.1 mM had the same effect as HgCl₂ inhibiting both demethylases and liver N-oxidase, but stimulating lung N-oxidase activity. However, 0.1 mM to 1 mMN-ethylmaleimide (NEM) and iodoacetamide had little if any effect on either liver or lung N-oxidase. It was also shown that Hg²⁺ effects on N-oxidase activity could be overcome by dilution.Changes in N,N-dimethyl aniline (DMA) metabolism with age were followed in rabbits from 4 days old to adult. There was a steady increase in lung demethylase activity and N-oxidase activity in the liver and lung to adult levels. However, the liver demethylase had a sharp increase in activity between 2 weeks and 1 month much like that seen with benzphetamine demethylase in rabbit liver.Activities of N-demethylase in liver and lung, and N-oxidr.se in liver from new-born rabbits were from 10 to 20 % of adult levels. However, in lung, N-oxidase activities in the newborn were about 50 % of adult levels. Microsomal N-oxidation in lungs from 2-day-old rabbits was stimulated by 0.1 mM mercury just as in the adult.     

Leucine aminopeptidase (bovine lens): Synthesis and kinetic properties of ortho-, meta-, and para-substituted leucyl-anilides

The synthesis of a number of leucyl derivatives of substituted anilides and their properties as substrates and inhibitors of Zn²⁺-Mg²⁺ leucine aminopeptidase (EC 3.4.11.1) at pH 8.5 and 30 °C are described. The compounds include leucyl-X where X is o-, m-, or p-aminobenzenesulfonic acid, o-, m-, or p-anisidine, and m- or p-aminobenzenesulfonyl fluoride. The latter two sulfonyl fluorides, designed to be active site-directed irreversible inhibitors, turned out to be good substrates for leucine aminopeptidase. The K_m and V values of the above compounds as substrates for leucine aminopeptidase are reported. N-Leucyl-m-aminobenzenesulfonate exhibits desirable properties (solubility much greater than K_m, Δ? at 295 nm of 2000 m^?1 cm^?1, and V of 300 μmol min^?1 mg^?1) as a substrate for a spectrophotometric assay of leucine aminopeptidase. With the exception of N-leucyl-p-aminobenzenesulfonate, all of the above compounds are inhibitors of the hydrolysis of leucyl-p-nitroanilide by leucine aminopeptidase with K_i values approximately their K_m values when they are used as substrates. Despite wide variability in steric bulk, chemical composition, and electrical charge of the substituted anilides, the K_m values of the above compounds vary over a narrow range (0.5 to 4.8 mm), which indicates that the leucyl moiety plays the predominant role in the determination of K_m values. Although the K_m values of m- substituents are similar to those of o- substituents, the V values for m-substituents are much greater than those for o- substituents, which suggests that o-substituents interfere with the catalytic process. N-Leucyl-p-aminobenzenesulfonate and N-alanyl-p-aminobenzenesulfonate as well as the nonsubstrate p-aminobenzenesulfonate stimulate rather than inhibit the proteolysis of leucyl-p-nitroanilide. The stimulation has no effect on V but lowers the K_m for the hydrolysis of leucyl-p-nitroanilide, which is compatible with these compounds' serving as nonessential activators.