Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Pivot Concepts:
Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Target Concepts:
Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Query: UNIPROT:P50583 (
asymmetrical
)
12,197
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
A study of the molar ratio dependence of the incorporation of alpha-tocopherol into single-lamellar vesicles showed that the number of molecules which the bilayers can accommodate increased linearly with increasing alpha-tocopherol/phosphatidylcholine initial molar ratios till about 0.05, then approached a saturation limit. At 5 mol%, one alpha-tocopherol molecule per 60 phospholipids can be incorporated into the membranes. Up to this limit the distribution of alpha-tocopherol in the bilayers is uniform, while at initial molar ratios higher than 0.05 a disproportionation toward the inner monolayer of the vesicles is observed. The average outer/total ratio is found to be 0.27 +/- 0.03 at alpha-tocopherol/phosphatidylcholine molar ratios above 0.07 and is similar to
asymmetrical
distributions that have been reported in vesicles containing other one-chain amphiphiles (e.g., cholesterol). This large disproportionation is in contrast with the packing distribution of certain two-chain amphiphiles, and indicates that one of the driving forces for asymmetry formation in lipid bilayers might be dependent on the number of hydrocarbon chains per amphiphile molecule. A possible reason for the disproportionation effect observed in our experiments is the displacement of unsaturated phospholipids to the outer monolayer of the single-lamellar vesicles, by the more rigid
isoprene
units of alpha-tocopherol.
...
PMID:Transmembrane distribution of alpha-tocopherol in single-lamellar mixed lipid vesicles. 721 32
Light-induced FTIR difference spectra of the photoreduction of the primary quinone acceptor QA have been obtained for Rhodobacter sphaeroides RCs reconstituted with a series of isotopically labeled quinones in order to separate the contributions of the quinone from those of the protein. The isotopic shifts observed in the QA-/QA spectra of RCs reconstituted with ubiquinones (Q1, Q6) or vitamin K1 18O-labeled on their carbonyl oxygens and with fully 13C-labeled Q8 lead to a clear identification of the quinone bands from both the neutral and anion forms. Double-difference spectra from pairs of QA-/QA spectra obtained from 18O/16O Q6, 18O/16O Q1, 13C/12C Q8, 13C18O/12C16O Q8, and 18O/16O vitamin K1 allow the C = O modes of QA in vivo to be identified unambiguously for the first time. For all the investigated unlabeled quinones, two carbonyl bands are demasked, at 1660 and 1628 cm-1 for neutral ubiquinones and at 1651 and 1640 cm-1 for vitamin K1, while C = C bands are found at 1608 and 1588 cm-1 for vitamin K1 and at 1601 cm-1 for ubiquinones. Compared with the spectra of the isolated quinones, the generally smaller width observed for the C = O and C = C bands in vivo suggests precise interactions between the quinone and the contours of the protein at a single, well-defined QA site. The different frequency downshifts of the two C = O bands upon binding to the QA site underscore the inequivalence of the two carbonyls in providing
asymmetrical
bonding interactions with the protein. The comparison of the isotopic shifts observed for the various quinone C = O and C = C bands in vitro and in vivo demonstrates that the admixture of C = O and C = C characters in these modes is strongly affected by the binding of QA to its anchoring site. In particular, the bands at 1628 and 1601 cm-1 of Q6 in vivo exhibit highly mixed C = O and C = C characters. In contrast, the methoxy groups of the ubiquinones do not appear to suffer large strain upon binding. The closeness of the QA-/QA spectra for Q1 and Q6 indicates that a possible role of the chain in providing the proper positioning of the quinone ring in the site for both the oxidized and reduced states of QA cannot extend significantly beyond the first
isoprene
unit.(ABSTRACT TRUNCATED AT 400 WORDS)
...
PMID:The binding sites of quinones in photosynthetic bacterial reaction centers investigated by light-induced FTIR difference spectroscopy: assignment of the QA vibrations in Rhodobacter sphaeroides using 18O- or 13C-labeled ubiquinone and vitamin K1. 816 57
Complexes [NNN]Ln(AlMe(4))(2) (Ln = Y, La, Nd, Lu) bearing the sterically demanding aryl-substituted triazenido ligand [(Tph)(2)N(3)] (Tph = [2-(2,4,6-iPr(3)C(6)H(2))C(6)H(4)]) can be obtained from homoleptic complexes Ln(AlMe(4))(3) in moderate yields, both via protonolysis with [(Tph)(2)N(3)]H and a salt metathesis reaction pathway utilizing [(Tph)(2)N(3)]K. In the solid state the Y and Lu derivatives are isostructural, with both tetramethylaluminate groups coordinated in an eta(2) fashion, while one of the [AlMe(4)] ligands of the Nd derivative features a distorted eta(2) coordination mode. Due to the high affinity of the triazenido ligand toward the more Lewis-acidic and harder aluminium cation compared to the softer rare-earth metal centres, ligand redistribution is observed in solution and formation of byproduct [(Tph)(2)N(3)]AlMe(2) is prominent. While the monoanionic triazenido ligand coordinates the rare-earth metal centres in an
asymmetrical
syn/anti fashion, it adopts an almost symmetric syn/syn configuration in the aluminium complex. Attempts were also made to produce putative dimethyl complexes {[(Tph)(2)N(3)]LnMe(2)} (Ln = Y, Lu) via cleavage of the aluminate moieties with diethyl ether. Furthermore, the intrinsic redistribution reactions are proposed to affect the performance of complexes [(Tph)(2)N(3)]Ln(AlMe(4))(2) in
isoprene
polymerization.
...
PMID:Rare-earth metal bis(tetramethylaluminate) complexes supported by a sterically crowded triazenido ligand. 2063 53
