Morphine and its pharmacological derivatives are the most prescribed analgesics for moderate to severe pain management. However, chronic use of morphine reduces pathogen clearance and induces bacterial translocation across the gut barrier. The enteric microbiome has been shown to play a critical role in the preservation of the mucosal barrier function and metabolic homeostasis. Here, we show for the first time, using bacterial 16s rDNA sequencing, that chronic morphine treatment significantly alters the gut microbial composition and induces preferential expansion of gram-positive pathogenic and reduction in bile-deconjugating bacterial strains. A significant reduction in both primary and secondary bile acid levels was seen in the gut, but not in the liver with morphine treatment. Morphine induced microbial dysbiosis and gut barrier disruption was rescued by transplanting placebo-treated microbiota into morphine-treated animals, indicating that Users may view, print, copy, and download text and data-mine the content in such documents, for the purposes of academic research, subject always to the full Conditions of use
The influence of posttranscriptional modification on structural stabilization of tRNA from hyperthermophilic archaea was studied, using Pyrococcus furiosus (growth optimum 100 degrees C) as a primary model. Optical melting temperatures (Tm) of unfractionated tRNA in 20 mM Mg2+ are 97 degrees C for P. furiosus and 101.5 degrees C for Pyrodictium occultum (growth optimum, 105 degrees C). These values are approximately 20 degrees C higher than predicted solely from G-C content and are attributed primarily to posttranscriptional modification. Twenty-three modified nucleosides were determined in total digests of P. furiosus tRNA by combined HPLC-mass spectrometry. From cells cultured at 70, 85, and 100 degrees C, progressively increased levels of modification were observed within three families of nucleosides, the most highly modified forms of which were N4-acetyl-2'-O-methylcytidine (ac4Cm), N2,N2,2'-O-trimethylguanosine (m2(2)Gm), and 5-methyl-2-thiouridine (m5s2U). Nucleosides ac4Cm and m2(2)Gm, which are unique to the archaeal hyperthermophiles, were shown in earlier NMR studies to exhibit unusually high conformational stabilities that favor the C3'-endo form [Kawai, G., et al. (1991) Nucleic Acids Symp. Ser. 21, 49-50; (1992) Nucleosides Nucleotides 11, 759-771]. The sequence location of m5s2U was determined by mass spectrometry to be primarily at tRNA position 54, a site of known thermal stabilization in the bacterial thermophile Thermus thermophilus [Horie, N., et al. (1985) Biochemistry 24, 5711-5715]. It is concluded that selected posttranscriptional modifications in archaeal thermophiles play major stabilizing roles beyond the effects of Mg2+ binding and G-C content, and are proportionally more important and have evolved with greater structural diversity at the nucleoside level in the bacterial thermophiles.
In order to further understand the structural role of the modified nucleoside dihydrouridine in RNA the solution conformations of Dp and ApDpA were analyzed by one- and two-dimensional proton NRM spectroscopy and compared with those of the related uridine-containing compounds. The analyses indicate that dihydrouridine significantly destabilizes the C3'-endo sugar conformation associated with base stacked, ordered, A-type helical RNA. Equilibrium constants (Keq = [C2'-endo]/[C3'-endo]) for C2'-endo-C3'-endo interconversion at 25 degrees C for Dp, the 5'-terminal A of ApDpA and D in ApDpA are 2.08, 1.35 and 10.8 respectively. Stabilization of the C2'-endo form was shown to be enhanced at low temperature, indicating that C2'-endo is the thermodynamically favored conformation for dihydrouridine. DeltaH values show that for Dp the C2'-endo sugar conformation is stabilized by 1.5 kcal/mol compared with Up. This effect is amplified for D in the oligonucleotide ApDpA and propagated to the 5'-neighboring A, with stabilization of the C2'-endo form by 5.3 kcal/mol for D and 3.6 kcal/mol for the 5'-terminal A. Post-transcriptional formation of dihydrouridine therefore represents a biological strategy opposite in effect to ribose methylation, 2-thiolation or pseudouridylation, all of which enhance regional stability through stabilization of the C3'-endo conformer. Dihydrouridine effectively promotes the C2'-endo sugar conformation, allowing for greater conformational flexibility and dynamic motion in regions of RNA where tertiary interactions and loop formation must be simultaneously accommodated.
Substrates homoprotocatechuate (HPCA) and O2 bind to the FeII of Homoprotocatechuate 2,3-dioxygenase (FeHPCD) in adjacent coordination sites. Transfer of an electron(s) from HPCA to O2 via the iron is proposed to activate the substrates for reaction with each other to initiate aromatic ring cleavage. Here, rapid-freeze-quench methods are used to trap and spectroscopically characterize intermediates in the reactions of the HPCA complexes of FeHPCD and the variant His200Asn (FeHPCD-HPCA and H200N-HPCA) with O2. A blue intermediate forms within 20 ms after mixing O2 with H200N-HPCA (H200NInt1HPCA). Parallel mode EPR and Mössbauer spectroscopies show that this intermediate contains high-spin FeIII (S=5/2) antiferromagnetically coupled to a radical (SR=1/2) to yield an S=2 state. Together, optical and Mössbauer spectra of the intermediate support assignment of the radical as an HPCA semiquinone, implying that oxygen is bound as a (hydro)peroxo ligand. H200NInt1HPCA decays over the next 2 s, possibly through an FeII intermediate (H200NInt2HPCA), to yield product and the resting FeII enzyme. Reaction of FeHPCD-HPCA with O2 results in rapid formation of a colorless FeII intermediate (FeHPCDInt1HPCA). This species decays within 1 s to yield the product and the resting enzyme. The absence of a chromophore from a semiquinone or evidence for a spin-coupled species in FeHPCDInt1HPCA suggests it is an intermediate occurring after O2 activation and attack. The similar Mössbauer parameters for FeHPCDInt1HPCA and H200NInt2HPCA suggest these are similar intermediates. The results show that electron transfer from the substrate to the O2 via the iron does occur leading to aromatic ring cleavage.
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